Emergence of second-order coherence in superfluorescence

TL;DR

This study experimentally demonstrates the emergence of second-order quantum coherence during superfluorescence in a chiral, cascaded atomic system, revealing insights into collective emission dynamics and fluctuations.

Contribution

It provides the first experimental observation of second-order coherence emergence in cascaded superfluorescence and compares it with symmetric coupling systems.

Findings

Second-order coherence appears during superfluorescence decay.

Fluctuations in burst delay are observed and correlated with photon emission events.

Superradiance features are similar in cascaded and symmetric coupling systems.

Abstract

We experimentally investigate the second-order quantum coherence function of a superradiant burst in a cascaded quantum system. We chirally (i.e. direction-dependently) couple roughly 900 cesium atoms to the forward propagating mode of an optical nanofiber. We then prepare the ensemble in the maximally inverted state, where the subsequent collective emission of a burst is known as superfluorescence. Here, we observe that second-order coherence emerges in the course of the decay. This is a clear feature of the underlying collective dynamics that is also at the origin of the superradiant burst itself. We furthermore study the dynamics of the second-order coherence function of the emission in dependence on the initial average dipole moment of the ensemble. In addition, by correlating the detection of early and late photon emission events, we obtain evidence for fundamental shot-to-shot fluctuations in the delay of the start of the burst emission. Our findings reveal that, despite the fundamentally different coupling Hamiltonian, superradiance in cascaded and symmetrically coupled systems feature a strikingly large number of similarities.